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v0.0.1

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Signed-off-by: Vitor Hideyoshi <vitor.h.n.batista@gmail.com>
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Vitor Hideyoshi
2021-06-17 20:01:42 -03:00
committed by Vitor Hideyoshi
commit 2899031b71
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DPpack/MolHandling.py Normal file
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import sys, math
import textwrap
from copy import deepcopy
import numpy as np
from numpy import linalg
from DPpack.PTable import *
from DPpack.SetGlobals import *
####################################### functions ######################################
def center_of_mass(molecule):
com = np.zeros(3)
total_mass = 0.0
for atom in molecule:
total_mass += atom['mass']
position = np.array([atom['rx'], atom['ry'], atom['rz']])
com += atom['mass'] * position
com = com / total_mass
return com
def center_of_mass_distance(molecule1, molecule2):
com1 = center_of_mass(molecule1)
com2 = center_of_mass(molecule2)
dx = com1[0] - com2[0]
dy = com1[1] - com2[1]
dz = com1[2] - com2[2]
distance = math.sqrt(dx**2 + dy**2 + dz**2)
return distance
def center_of_mass_to_origin(molecule):
com = center_of_mass(molecule)
for atom in molecule:
atom['rx'] -= com[0]
atom['ry'] -= com[1]
atom['rz'] -= com[2]
return
def charges_and_dipole(molecule):
eA_to_Debye = 1/0.20819434
charge = 0
dipole = np.zeros(3)
for atom in molecule:
position = np.array([ atom['rx'], atom['ry'], atom['rz'] ])
dipole += atom['chg'] * position
charge += atom['chg']
dipole *= eA_to_Debye
total_dipole = math.sqrt(dipole[0]**2 + dipole[1]**2 + dipole[2]**2)
return [charge, dipole[0], dipole[1], dipole[2], total_dipole]
def distances_between_atoms(molecule):
distances = []
dim = len(molecule)
for atom1 in molecule:
if atom1['na'] != ghost_number:
for atom2 in molecule:
if atom2['na'] != ghost_number:
dx = atom1['rx'] - atom2['rx']
dy = atom1['ry'] - atom2['ry']
dz = atom1['rz'] - atom2['rz']
distances.append(math.sqrt(dx**2 + dy**2 + dz**2))
return np.array(distances).reshape(dim, dim)
def eixos(molecule):
eixos = np.zeros(3)
if len(molecule) == 2:
position1 = np.array([ molecule[0]['rx'], molecule[0]['ry'], molecule[0]['rz'] ])
position2 = np.array([ molecule[1]['rx'], molecule[1]['ry'], molecule[1]['rz'] ])
eixos = position2 - position1
eixos /= linalg.norm(eixos)
elif len(molecule) > 2:
position1 = np.array([ molecule[0]['rx'], molecule[0]['ry'], molecule[0]['rz'] ])
position2 = np.array([ molecule[1]['rx'], molecule[1]['ry'], molecule[1]['rz'] ])
position3 = np.array([ molecule[2]['rx'], molecule[2]['ry'], molecule[2]['rz'] ])
v1 = position2 - position1
v2 = position3 - position1
v3 = np.cross(v1, v2)
v2 = np.cross(v1, v3)
v1 /= linalg.norm(v1)
v2 /= linalg.norm(v2)
v3 /= linalg.norm(v3)
eixos = np.array([[v1[0], v1[1], v1[2]],
[v2[0], v2[1], v2[2]],
[v3[0], v3[1], v3[2]]])
return eixos
def inertia_tensor(molecule):
com = center_of_mass(molecule)
Ixx = Ixy = Ixz = Iyy = Iyz = Izz = 0.0
for atom in molecule:
#### Obtain the displacement from the center of mass
dx = atom['rx'] - com[0]
dy = atom['ry'] - com[1]
dz = atom['rz'] - com[2]
#### Update the diagonal components of the tensor
Ixx += atom['mass'] * (dy**2 + dz**2)
Iyy += atom['mass'] * (dz**2 + dx**2)
Izz += atom['mass'] * (dx**2 + dy**2)
#### Update the off-diagonal components of the tensor
Ixy += atom['mass'] * dx * dy * -1
Ixz += atom['mass'] * dx * dz * -1
Iyz += atom['mass'] * dy * dz * -1
return np.array([[Ixx, Ixy, Ixz],
[Ixy, Iyy, Iyz],
[Ixz, Iyz, Izz]])
def minimum_distance(molecule1, molecule2):
distances = []
for atom1 in molecule1:
if atom1['na'] != ghost_number:
for atom2 in molecule2:
if atom2['na'] != ghost_number:
dx = atom1['rx'] - atom2['rx']
dy = atom1['ry'] - atom2['ry']
dz = atom1['rz'] - atom2['rz']
distances.append(math.sqrt(dx**2 + dy**2 + dz**2))
return min(distances)
def nearest_image(refmol, molecule, lx, ly, lz, criterium="com"):
if criterium != "com" and criterium != "min":
sys.exit("Error in value passed to function nearest_image")
min_dist = 1e20
for i in range(-1, 2):
for j in range(-1, 2):
for k in range(-1, 2):
tr_vector = [i * lx, j * ly, k * lz]
new_molecule = translate(molecule, tr_vector)
if criterium == "com":
dist = center_of_mass_distance(refmol, new_molecule)
else:
dist = minimum_distance(refmol, new_molecule)
if dist < min_dist:
min_dist = dist
nearestmol = deepcopy(new_molecule)
return min_dist, nearestmol
def calculate_step(gradient, hessian, fh):
invhessian = linalg.inv(hessian)
pre_step = -1 * np.matmul(invhessian, gradient.T).T
maxstep = np.amax(np.absolute(pre_step))
factor = min(1, player['maxstep']/maxstep)
step = factor * pre_step
fh.write("\nCalculated step:\n")
pre_step_list = pre_step.tolist()
fh.write("-----------------------------------------------------------------------\n"
"Center Atomic Step (Bohr)\n"
"Number Number X Y Z\n"
"-----------------------------------------------------------------------\n")
for i in range(len(molecules[0])):
fh.write(" {:>5d} {:>3d} {:>14.9f} {:>14.9f} {:>14.9f}\n".format(
i + 1, molecules[0][i]['na'],
pre_step_list.pop(0), pre_step_list.pop(0), pre_step_list.pop(0)))
fh.write("-----------------------------------------------------------------------\n")
fh.write("Maximum step is {:>11.6}\n".format(maxstep))
fh.write("Scaling factor = {:>6.4f}\n".format(factor))
fh.write("\nFinal step (Bohr):\n")
step_list = step.tolist()
fh.write("-----------------------------------------------------------------------\n"
"Center Atomic Step (Bohr)\n"
"Number Number X Y Z\n"
"-----------------------------------------------------------------------\n")
for i in range(len(molecules[0])):
fh.write(" {:>5d} {:>3d} {:>14.9f} {:>14.9f} {:>14.9f}\n".format(
i + 1, molecules[0][i]['na'],
step_list.pop(0), step_list.pop(0), step_list.pop(0)))
fh.write("-----------------------------------------------------------------------\n")
step_max = np.amax(np.absolute(step))
step_rms = np.sqrt(np.mean(np.square(step)))
fh.write(" Max Step = {:>14.9f} RMS Step = {:>14.9f}\n\n".format(
step_max, step_rms))
return step
def read_position(molecule):
position_list = []
for atom in molecule:
position_list.extend([ atom['rx'], atom['ry'], atom['rz'] ])
position = np.array(position_list)
position *= ang2bohr
return position
def update_molecule(position, fh):
position_in_ang = (position * bohr2ang).tolist()
new_molecule = deepcopy(molecules[0])
for atom in new_molecule:
atom['rx'] = position_in_ang.pop(0)
atom['ry'] = position_in_ang.pop(0)
atom['rz'] = position_in_ang.pop(0)
rmsd, molecules[0] = rmsd_fit(new_molecule, molecules[0])
fh.write("\nProjected new conformation of reference molecule with RMSD fit\n")
fh.write("RMSD = {:>8.5f} Angstrom\n".format(rmsd))
return
def update_hessian(step, cur_gradient, old_gradient, hessian): ## According to the BFGS
dif_gradient = cur_gradient - old_gradient
mat1 = 1/np.dot(dif_gradient, step) * np.matmul(dif_gradient.T, dif_gradient)
mat2 = 1/np.dot(step, np.matmul(hessian, step.T).T)
mat2 *= np.matmul( np.matmul(hessian, step.T), np.matmul(step, hessian) )
hessian += mat1 - mat2
return hessian
def populate_asec_vdw(cycle, fh):
asec_charges = [] # (rx, ry, rz, chg)
vdw_meanfield = [] # (rx, ry, rz, eps, sig)
if dice['nstep'][-1] % dice['isave'] == 0:
nconfigs = round(dice['nstep'][-1] / dice['isave'])
else:
nconfigs = int(dice['nstep'][-1] / dice['isave'])
norm_factor = nconfigs * player['nprocs']
nsitesref = len(molecules[0]) + len(ghost_atoms) + len(lp_atoms)
nsites_total = dice['nmol'][0] * nsitesref
for i in range(1, len(dice['nmol'])):
nsites_total += dice['nmol'][i] * len(molecules[i])
thickness = []
picked_mols = []
for proc in range(1, player['nprocs'] + 1): ## Run over folders
path = "step{:02d}".format(cycle) + os.sep + "p{:02d}".format(proc)
file = path + os.sep + dice['outname'] + ".xyz"
if not os.path.isfile(file):
sys.exit("Error: cannot find file {}".format(file))
try:
with open(file) as xyzfh:
xyzfile = xyzfh.readlines()
except:
sys.exit("Error: cannot open file {}".format(file))
for config in range(nconfigs): ## Run over configs in a folder
if int( xyzfile.pop(0).split()[0] ) != nsites_total:
sys.exit("Error: wrong number of sites in file {}".format(file))
box = xyzfile.pop(0).split()[-3:]
box = [ float(box[0]), float(box[1]), float(box[2]) ]
sizes = sizes_of_molecule(molecules[0])
thickness.append( min([ (box[0] - sizes[0])/2, (box[1] - sizes[1])/2,
(box[2] - sizes[2])/2 ]) )
xyzfile = xyzfile[nsitesref:] ## Skip the first (reference) molecule
mol_count = 0
for type in range(len(dice['nmol'])): ## Run over types of molecules
if type == 0:
nmols = dice['nmol'][0] - 1
else:
nmols = dice['nmol'][type]
for mol in range(nmols): ## Run over molecules of each type
new_molecule = []
for site in range(len(molecules[type])): ## Run over sites of each molecule
new_molecule.append({})
line = xyzfile.pop(0).split()
if line[0].title() != atomsymb[molecules[type][site]['na']].strip():
sys.exit("Error reading file {}".format(file))
new_molecule[site]['na'] = molecules[type][site]['na']
new_molecule[site]['rx'] = float(line[1])
new_molecule[site]['ry'] = float(line[2])
new_molecule[site]['rz'] = float(line[3])
new_molecule[site]['chg'] = molecules[type][site]['chg']
new_molecule[site]['eps'] = molecules[type][site]['eps']
new_molecule[site]['sig'] = molecules[type][site]['sig']
dist = minimum_distance(molecules[0], new_molecule)
if dist < thickness[-1]:
mol_count += 1
for atom in new_molecule:
asec_charges.append({})
vdw_meanfield.append({})
asec_charges[-1]['rx'] = atom['rx']
asec_charges[-1]['ry'] = atom['ry']
asec_charges[-1]['rz'] = atom['rz']
asec_charges[-1]['chg'] = atom['chg'] / norm_factor
if player['vdwforces'] == "yes":
vdw_meanfield[-1]['rx'] = atom['rx']
vdw_meanfield[-1]['ry'] = atom['ry']
vdw_meanfield[-1]['rz'] = atom['rz']
vdw_meanfield[-1]['eps'] = atom['eps']
vdw_meanfield[-1]['sig'] = atom['sig']
#### Read lines with ghosts or lps in molecules of type 0 (reference)
#### and, if dist < thickness, appends to asec
if type == 0:
for ghost in ghost_atoms:
line = xyzfile.pop(0).split()
if line[0] != dice_ghost_label:
sys.exit("Error reading file {}".format(file))
if dist < thickness[-1]:
asec_charges.append({})
asec_charges[-1]['rx'] = float(line[1])
asec_charges[-1]['ry'] = float(line[2])
asec_charges[-1]['rz'] = float(line[3])
asec_charges[-1]['chg'] = ghost['chg'] / norm_factor
for lp in lp_atoms:
line = xyzfile.pop(0).split()
if line[0] != dice_ghost_label:
sys.exit("Error reading file {}".format(file))
if dist < thickness[-1]:
asec_charges.append({})
asec_charges[-1]['rx'] = float(line[1])
asec_charges[-1]['ry'] = float(line[2])
asec_charges[-1]['rz'] = float(line[3])
asec_charges[-1]['chg'] = lp['chg'] / norm_factor
picked_mols.append(mol_count)
fh.write("Done\n")
string = "In average, {:^7.2f} molecules ".format(sum(picked_mols)/norm_factor)
string += "were selected from each of the {} configurations ".format(len(picked_mols))
string += "of the production simulations to form the ASEC, comprising a shell with "
string += "minimum thickness of {:>6.2f} Angstrom\n".format(sum(thickness)/norm_factor)
fh.write(textwrap.fill(string, 86))
fh.write("\n")
otherfh = open("ASEC.dat", "w")
for charge in asec_charges:
otherfh.write("{:>10.5f} {:>10.5f} {:>10.5f} {:>11.8f}\n".format(
charge['rx'], charge['ry'], charge['rz'], charge['chg']))
otherfh.close()
return asec_charges
def principal_axes(inertia_tensor):
try:
evals, evecs = linalg.eigh(inertia_tensor)
except:
sys.exit("Error: diagonalization of inertia tensor did not converge")
return evals, evecs
def print_geom(cycle, fh):
fh.write("{}\n".format(len(molecules[0])))
fh.write("Cycle # {}\n".format(cycle))
for atom in molecules[0]:
symbol = atomsymb[atom['na']]
fh.write("{:<2s} {:>10.6f} {:>10.6f} {:>10.6f}\n".format(symbol,
atom['rx'], atom['ry'], atom['rz']))
return
def print_mol_info(molecule, fh):
com = center_of_mass(molecule)
fh.write(" Center of mass = ( {:>10.4f} , {:>10.4f} , {:>10.4f} )\n".format(com[0],
com[1], com[2]))
inertia = inertia_tensor(molecule)
evals, evecs = principal_axes(inertia)
fh.write(" Moments of inertia = {:>9E} {:>9E} {:>9E}\n".format(evals[0],
evals[1], evals[2]))
fh.write(" Major principal axis = ( {:>10.6f} , {:>10.6f} , {:>10.6f} )\n".format(
evecs[0,0], evecs[1,0], evecs[2,0]))
fh.write(" Inter principal axis = ( {:>10.6f} , {:>10.6f} , {:>10.6f} )\n".format(
evecs[0,1], evecs[1,1], evecs[2,1]))
fh.write(" Minor principal axis = ( {:>10.6f} , {:>10.6f} , {:>10.6f} )\n".format(
evecs[0,2], evecs[1,2], evecs[2,2]))
sizes = sizes_of_molecule(molecule)
fh.write(" Characteristic lengths = ( {:>6.2f} , {:>6.2f} , {:>6.2f} )\n".format(
sizes[0], sizes[1], sizes[2]))
mol_mass = total_mass(molecule)
fh.write(" Total mass = {:>8.2f} au\n".format(mol_mass))
chg_dip = charges_and_dipole(molecule)
fh.write(" Total charge = {:>8.4f} e\n".format(chg_dip[0]))
fh.write(" Dipole moment = ( {:>9.4f} , {:>9.4f} , {:>9.4f} ) Total = {:>9.4f} Debye\n\n".format(
chg_dip[1], chg_dip[2], chg_dip[3], chg_dip[4]))
return
def sizes_of_molecule(molecule):
x_list = []
y_list = []
z_list = []
for atom in molecule:
if atom['na'] != ghost_number:
x_list.append(atom['rx'])
y_list.append(atom['ry'])
z_list.append(atom['rz'])
x_max = max(x_list)
x_min = min(x_list)
y_max = max(y_list)
y_min = min(y_list)
z_max = max(z_list)
z_min = min(z_list)
sizes = [x_max - x_min, y_max - y_min, z_max - z_min]
return sizes
def standard_orientation(molecule):
center_of_mass_to_origin(molecule)
tensor = inertia_tensor(molecule)
evals, evecs = principal_axes(tensor)
if round(linalg.det(evecs)) == -1:
evecs[0,2] *= -1
evecs[1,2] *= -1
evecs[2,2] *= -1
if round(linalg.det(evecs)) != 1:
sys.exit("Error: could not make a rotation matrix while adopting the standard orientation")
rot_matrix = evecs.T
for atom in molecule:
position = np.array([ atom['rx'], atom['ry'], atom['rz'] ])
new_position = np.matmul(rot_matrix, position.T).T
atom['rx'] = new_position[0]
atom['ry'] = new_position[1]
atom['rz'] = new_position[2]
return
def total_mass(molecule):
mass = 0
for atom in molecule:
mass += atom['mass']
return mass
def translate(molecule, vector):
new_molecule = deepcopy(molecule)
for atom in new_molecule:
atom['rx'] += vector[0]
atom['ry'] += vector[1]
atom['rz'] += vector[2]
return new_molecule
def rmsd_fit(projecting_mol, reference_mol):
if len(projecting_mol) != len(reference_mol):
sys.exit("Error in RMSD fit procedure: molecules have different number of atoms")
dim = len(projecting_mol)
new_projecting_mol = deepcopy(projecting_mol)
new_reference_mol = deepcopy(reference_mol)
center_of_mass_to_origin(new_projecting_mol)
center_of_mass_to_origin(new_reference_mol)
x = []
y = []
for atom in new_projecting_mol:
x.extend([ atom['rx'], atom['ry'], atom['rz'] ])
for atom in new_reference_mol:
y.extend([ atom['rx'], atom['ry'], atom['rz'] ])
x = np.array(x).reshape(dim, 3)
y = np.array(y).reshape(dim, 3)
r = np.matmul(y.T, x)
rr = np.matmul(r.T, r)
try:
evals, evecs = linalg.eigh(rr)
except:
sys.exit("Error: diagonalization of RR matrix did not converge")
a1 = evecs[:,2].T
a2 = evecs[:,1].T
a3 = np.cross(a1, a2)
A = np.array([ a1[0], a1[1], a1[2], a2[0], a2[1], a2[2], a3[0], a3[1], a3[2] ])
A = A.reshape(3,3)
b1 = np.matmul(r, a1.T).T # or np.dot(r, a1)
b1 /= linalg.norm(b1)
b2 = np.matmul(r, a2.T).T # or np.dot(r, a2)
b2 /= linalg.norm(b2)
b3 = np.cross(b1, b2)
B = np.array([ b1[0], b1[1], b1[2], b2[0], b2[1], b2[2], b3[0], b3[1], b3[2] ])
B = B.reshape(3,3).T
rot_matrix = np.matmul(B, A)
x = np.matmul(rot_matrix, x.T).T
rmsd = 0
for i in range(dim):
rmsd += (x[i,0] - y[i,0])**2 + (x[i,1] - y[i,1])**2 + (x[i,2] - y[i,2])**2
rmsd = math.sqrt(rmsd/dim)
for i in range(dim):
new_projecting_mol[i]['rx'] = x[i,0]
new_projecting_mol[i]['ry'] = x[i,1]
new_projecting_mol[i]['rz'] = x[i,2]
tr_vector = center_of_mass(reference_mol)
projected_mol = translate(new_projecting_mol, tr_vector)
return rmsd, projected_mol